Coherent light generators – Particular resonant cavity – Distributed feedback
Patent
1998-05-06
2000-11-28
Font, Frank G.
Coherent light generators
Particular resonant cavity
Distributed feedback
372 96, 372 92, 372 45, 372 98, 372 99, 372 64, 372102, H01S 308
Patent
active
061544809
ABSTRACT:
A new class of vertical-cavity lasers (VCLs) is disclosed. Conventional VCLs contain an active region enclosed by Bragg-mirror stacks of 30-100 quarter-wave layers. The new VCLs can be fabricated without Bragg mirrors by replacing them with efficient diffractive (guided-mode resonance (GMR)) mirrors with much fewer layers, for example, two or three layers. This application provides optical power flow across and along the VCL gain region, thereby greatly increasing the laser efficiency and reducing the threshold mirror reflectance needed for lasing, relative to conventional VCLs. Theoretical and experimental results show that GMR mirrors exhibit high reflectance (theoretically, 100%; experimentally, in excess of 90%) in a narrow spectral band with well-defined polarization states. When incorporated in VCLs, the GMR mirrors yield single-mode, narrow-line, highly-polarized output light. The GMR-VCL is independent of any particular material system. An example fabrication process of GaAs-based VCLs includes molecular-beam epitaxial growth of the basic planar structure and multiple-quantum-well (InGaAs/GaAs for 980 nm wavelength) active layers, interferometric recording of the GMR grating, lithographic and reactive-ion-etch definition of individual VCL elements, and metallization and contacting. GMR-VCL arrays can also be fabricated; the diffractive element will phase-lock the individual lasers to produce exceptionally high optical power and coherence. GMR-VCL technology holds high potential to provide low-cost, high-speed sources for fiber optic communications and other applications.
REFERENCES:
patent: 5216680 (1993-06-01), Magnusson et al.
patent: 5264715 (1993-11-01), Guenter et al.
patent: 5598300 (1997-01-01), Magnusson et al.
patent: 5625729 (1997-04-01), Brown
patent: 5783319 (1998-07-01), Reisfeld et al.
Alavi, "Molecular Beam Epitaxy, " In Handbook of Compound Semiconductors, P. H. Holloway and G. E. McGuire, Eds., pp. 84-169, Noyes Publications 1995.
Avrutsky and Sychugov, "Reflection of a beam of finite size from a corrugated waveguide," J. Mod. Opt. 36, 1527-1539, 1989.
Chua et al., "Indium tin oxide transparent electrodes for broad-area top-emitting vertical-cavity lasers fabricated using a single lithography step," IEEE Photonics Tech. Lett. 9, 551-553, 1997.
Gourley and Warren, "Surface-emitting semiconductor laser structures fabricated by microlithography," J. Nonlinear Opt. Phys. and Materials 4, 27-81, 1995.
Jewell et al., "Vertical-cavity surface-emitting lasers: Design, growth, fabrication, characterization," IEEE J. Quantum Electron. 27, 1332-1346, 1991.
Magnusson and Wang, "New principle for optical filters," Appl. Phys. Lett. 61, 1022-1024, 1992.
Margalit et al., "Vertical cavity lasers for telecom applications," IEEE Communication Magazine, 164-170, 1997.
Wang and Magnusson, "Design of waveguide-grating filters with symmetrical line shapes and low sidebands," Optics Lett. 19, 919-921, 1994.
Yariv, "Optical Electronics," In Modern Communications, 5th Ed., Oxford University Press, New York, p. 628-636, 1997.
Magnusson Robert
Shin Dong-ho
Young Preston P.
Board of Regents , The University of Texas System
Flores Ruiz Delma R.
Font Frank G.
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